171
Macromolecules 1980, 13, 171-176
Fast Neutron Irradiation Effects on Polymers. 2. Cross-Linking and Degradation of Polystyrene Shigenori Egusa,' Kenkichi Ishigure, a n d Yoneho Tabata* Nuclear Engineering Research Laboratory, The University of Tokyo, Tokai-mura, Zbaraki 319-11, Japan. Received July 13, 1979
ABSTRACT: Irradiation effects of fast neutrons on polystyrene were compared with those of 6oCoy-rays from the viewpoint of linear energy transfer (LET). For in vacuo irradiations, the G values of cross-links and main-chain scissions, G(X) and G(S), are 0.036 and 0.022, respectively, for y-rays of low L E T (ca. 0.02 eV/A). Fast neutrons of high L E T (ca. 3.7 eV/& increase not only the G(X) value to 0.14-0.26, depending on the initial molecular weight of polystyrene, but also the G(S) value to 0.22. For in air irradiations, oxygen increases the G(S) value by a factor of about 7 without affecting the G(X) value appreciably for y-rays, whereas for fast neutrons oxygen decreases both the G(X) and G(S) values to about 1/3 and 1/2 those obtained in vacuo, respectively. As to the change in the molecular weight distribution by irradiation, the MJM, ratio of polystyrene irradiated with fast neutrons in vacuo increases much more rapidly than that with y-rays as the number of cross-linked units increases, suggesting the nonrandom cross-linking at high LET. All of these findings are explained qualitatively by a difference in the spatial distribution of microscopic energy deposition and the resulting reactive species between fast neutrons and y-rays. The computer simulation shows that nonrandom cross-linking actually takes place at high LET, and it is caused by the microscopic inhomogeneity of energy deposition.
In a previous paper,2 we reported the study on the fast-neutron irradiation effects of poly(methy1 methacrylate) (PMMA). The study demonstrated that the G value of main-chain scissions due to fast neutrons is different from that due to 6oco y-rays because of a difference in linear energy transfer (LET), and furthermore the degradation does not take place a t random especially for fast-neutron irradiation due to the increased inhomogeneity of energy deposition on a microscopic scale. These LET effects may be observed more clearly for cross-linking polymers than for predominantly degrading polymers such as PMMA, since the difference in LET will have a more striking influence on the bimolecular reaction of cross-linking rather than on the essentially unimolecular reaction of degradation. From these points of view, we studied the fast-neutron and 6oCoy-ray irradiation effects on polystyrene concerning the G values of cross-links and main-chain scissions and the change in the molecular weight distribution and were able to find clearly the LET effects caused by the two types of radiation3 The present paper mainly describes the LET effects and the interpretation made on the same basis as previously mentioned for the degradation of PMMA.2 Experimental Section Two samples of monodisperse polystyrene powder with molecular weights of 1.1 X lo5 and 3.9 x lo5 (Pressure Chemical Co.) were used without further purification, and the irradiation procedure was the same as that previously described.2 The fastneutron reactor used here and the procedure of the in-reactor dosimetry were the same as those described in previous paper^.^^^ The @Coy-ray irradiations were made a t room temperature a t a dose rate of about 0.6 Mrad/h. For in-reactor irradiations, the sample temperature was kept below 33 "C during irradiation, and the dose rates due to fast neutrons and the concomitant y-rays were 1.30 (86%) and 0.22 Mrad/h (14%), respectively. Measurements of molecular weight distribution were carried out with the same gel-permeation chromatography (GPC) apparatus and procedures as previously described.2 The solid curve in Figure 1shows the GPC calibration curve obtained from eight standard samples of monodisperse linear polystyrene (Pressure Chemical Co.). The GPC calibration curve for cross-linked polystyrene was calculated according to the method described by Drott and Mendelsod for branched polymers. The calculation was made by assuming that the number of branch points per molecule is equal to that of cross-link points per molecule and that the number of macromoleculessubjected to both cross-linking 0024-9297/80/2213-0171$01.00/0
and main-chain scission is negligibly small at low absorbed doses in the pre-gel region. Then the number of branch points per molecule was estimated simply by dividing the molecular weight of cross-linked polystyrene by the initial molecular weight and subtracting 1from the quotient. The GPC calibration curves thus determined for cross-linked polystyrene whose initial molecular weight is 1.1X lo5 and 3.9 X lo5 are shown in Figure 1 by the broken and dash-dot curves, respectively. Using these calibration curves, we calculated the molecular weight distribution and the number-, weight-, and z-average molecular weights, M,,M,, and M,,from the GPC chromatogram.
Results 1. G Values of Cross-Links a n d Main-Chain Scissions. Typical examples of the molecular weight distributions obtained after irradiation with 6oCoy-rays and fast neutrons are shown in Figure 2a,b, respectively, by the solid (in vacuo) and dash-dot curves (in air) together with that before irradiation (broken curve) for the polystyrene sample with an initial molecular weight of 3.9 X lo5 (M,/M, = 1.10). It is seen from Figure 2a that crosslinking predominates over degradation for polystyrene irradiated with y-rays in vacuo, whereas in air the predominance is reversed. In fact, gelation took place at about 47 Mrad in vacuo, but in air it was not observed even a t 120 Mrad. For fast-neutron irradiations, on the other hand, cross-linking predominates in both cases as seen from Figure 2b, and gelation was actually observed both in vacuo (at about 21 Mrad) and in air (at about 35 Mrad). The results obtained from the polystyrene sample with an initial molecular weight of 1.1X lo5 (MJM,, = 1.06) were essentially the same as those described above. When the molecular weight distribution before irradiation is adequately approximated by the Schultz-Zimm distrib~tion,~~' the G values of cross-links and main-chain scissions, G(X)and G W , can be determined a t the same time by solving the following two simultaneous equations which were derived by Saito8 on the assumption that cross-linking and main-chain scission take place at random
M,o -=
(UT)'/2[U7 -
Mw where ux and u7
1 4- (1 f UT/^)-*] - 2 U x
0 1980 American Chemical Society
172 Egusa, Ishigure, Tabata
Macromolecules
nI
1Vln
ux =
0.965
o
X
lo6
(3)
Mno (4) 0.965 X lo6 are parameters standing for the numbers of cross-linked units and main-chain scissions per initial number-average molecule, respectively, M,O is the number-average molecular weight before irradiation, u is the degree of polymerization of M,O, b is a parameter indicating the narrowness of the Schultz-Zimm distribution breadth, and D is the absorbed dose in Mrad. Simultaneous eq 1 and 2 in ux and UT were solved by using a computer for each irradiated sample whose M , and M , values were available from the GPC chromatogram. The ux and UT values thus determined were first converted to the values corresponding to G ( X ) Dand G ( S ) Dby using eq 3 and 4, respectively, and then the G ( X ) Dand G ( S ) D values were plotted as a function of D. As to samples irradiated in the reactor, the G ( X ) D and G ( S ) D values corrected for the concomitant y-ray contributions were plotted as a function of the absorbed dose due to fast neutrons, D,. This correction was made by subtracting the y-ray contributions, G,(X)D, and G,(S)D,, using the G,(X) and G,(S) values determined here for “Co y-ray irradiation and the D, value measured by the in-reactor d o ~ i m e t r y .Examples ~ of the plots obtained in this way are shown in Figure 3a,b for polystyrene (Mn0= 3.9 X lo5) irradiated in air with 6oCoy-rays and fast neutrons, respectively. The slopes of these linear plots and the least-squares method give the G ( X ) and G ( S ) values and their 95% confidence limits, which are collected in Table I together with the values of 2 G ( X ) + G ( S )and G ( S ) / G ( X ) . The value of 2 G ( X ) + G ( S ) corresponds to the G value of the polymeric intermediates which either form intermolecular cross-links by the combination or dissociate spontaneously into two macromolecules. 2. Change in Molecular Weight Distribution. The change in the molecular weight distribution by irradiation can be followed by plotting the ratios of M,/M, and M z / M , as a function of ux,i.e., the number of cross-linked units per initial number-average molecule. The plots obtained for the polystyrene sample with an initial molecular weight of 3.9 X lo5 are shown in Figure 4. The plots for in air irradiation (Figure 4b) demonstrate that both the M,/M, and M J M , ratios increase with ux more rapidly for fast neutrons than for y-rays, and that these ratios for y-rays appear to level off at ux values of 1.0 or above. This finding corresponds to the fact that gelation does not take place in polystyrene irradiated in air with y-rays but does take place even in air with fast neutrons. On the other hand, the plots for in vacuo irradiation (Figure 4a) indicate that the M,/M, ratio increases with ux much more rapidly for fast neutrons than for y-rays, although the M,/M, ratio increases similarly for both types of radiation. These characteristics of the M,/M, and M z / M , changes with ux were essentially the same for the polystyrene sample with an initial molecular weight of 1.1 X lo5. UT
”
t
=
5
--,L3
Discussion 1. Accuracy of G(X)and G ( S ) . Our G ( X ) and G ( S ) values in Table I were evaluated from eq 1 and 2 which have been derived by assuming that cross-linking and main-chain scission take place at random.8 However, our previous work on the degradation of PMMA2 demonstrated that the main-chain scission does not take place at random for fast-neutron irradiation because of the microscopic inhomogeneity of energy deposition, and that
4
2 1
30
40 50 Elution volume (ml)
Figure 1. GPC calibration curves of the elution volume vs. the molecular weight for linear polystyrene (solid curve) and for branched polystyrene which is produced by cross-linking of monodisperse polystyrene with an initial molecular weight of 1.1 x lo5 (broken curve) or 3.9 X lo6 (dash-dot curve). 2.5
t
(a) 6oCo 7-Rays
2.0
-
1.01
2.5
2.0
‘
1
1
I
iA
/
!
\Il
i /
( b ) Fast Neutrons
I
I I
log M
Figure 2. Molecular weight distributions of polystyrene before (broken curve) and after irradiations in a @‘Co y-ray source (a) and in the fast-neutron reactor (b) in vacuo (solid curve) and in air (dash-dot curve). Absorbed doses (Mrad) are as follows: 25.8 (in vacuo) and 38.9 (in air) for (a); 6.3 (in vacuo) and 12.5 (in air) for (b).
the inhomogeneity makes the M , value somewhat higher than that predicted by the random degradation theory. For the exact evaluation of G ( X )and G ( S ) ,therefore, eq
Cross-Linking and Degradation of Polystyrene 173
Vol. 13, No.1, January-February 1980
Table I G Values of Cross-Links and Main-Chain Scissions of Polystyrene for 6oCoy-Rays and Fast Neutrons in vacuo initial mol wt
G(X)
1.1 x 105
G(S)
105 105
3.9 x 1.1 x 3.9 x 1.1 x 3.9 x 1.1 x 3.9 x
2G(X) + G(S) G(S)IG(X)
5t
y -rays
0.036 0.033 0.019 0.030 0.091 0.096 0.54 0.92
105 105 105 105 105
t i
i k f
i
0.001 0.007 0.007 0.021 0.009 0.035
in air neutrons
0.264 0.142 0.209 0.225 0.737 0.509 0.79 1.59
i i i
i i
t
0.079 0.040 0.093 0.057 0.251 0.137
neutrons
y-rays
0.031 t 0.006 0.034 I 0.004 0.150 i 0.051 0.143 i 0.020 0.212 t 0.063 0.211 t 0.028
4.93 4.17
t 0.019 0.055 t 0.009 0.089 i 0.020 0.111 i 0.026 0.259 2 0.058 0.221 i 0.044 1.05 2.04
0.085
(b) Fast Neutrons
,I
,
121
(b) i n air l l t
I
c3
(32 x , XX '
I
10
I
20 Dn
I
30
I
1
/ -c
40
:-eci
(Mrad)
Figure 3. Plot of the number of cross-links ( X ) or main-chain scissions ( 0 )vs. the absorbed dose D, due to 'Wo y-rays (a) and D, due to fast neutrons (b) for polystyrene with an initial molecular weight of 3.9 X lo5 irradiated in air. For (b), corrections are made for the concomitant y-rays by the term G P , (see text).
2 which expresses the M , change must be modified to hold even for nonrandom cross-linking and degradation by introducing a parameter expressing the degree of the microscopic inhomogeneity of energy deposition, i.e., A D / x in our previous paper.2 Even if the modified equation should be obtained, however, the additional parameter of a O / x will make it too complex to be used for the evaluation of G values. For this reason, we used eq 2 without modification as an approximation in the evaluation of the G(X) and G(S) values. Our G(X) values for y irradiation in vacuo are within the variation in the reported values of 0.019-0.051.~17 However, our G(X) values for fast-neutron irradiation in vacuo are slightly higher than the reported value of 0.096.12 Our G(S) values, on the other hand, are considerably higher compared with the reported values of O.OOO86 and 0.022 for in vacuo and in air y irradiation,16J8respectively, and are so compared with the reported value of 0.027 for fast neutrons in vacuo.12 Nevertheless, G(S) values similar
ux Figure 4. Plot of the M,/M, (0,0 ) and M J M , (0, W) ratios for in vacuo (a) and in air irradiations (b) with @'Co y-rays (open points) and fast neutrons (solid points) as a function of the number of cross-linked units per initial number-averagemolecule, ux,for polystyrene with an initial molecular weight of 3.9 X los.
to ours, 0.01914and 0.010-0.051," are also reported for y irradiation in vacuo. The wide variation in the G(X) and G(S) values among workers seems to arise mainly from differences in the sample preparation, the irradiation conditions, and the method used to evaluate the G values. In this connection, it should be noted that the G(S)/G(X) ratios in Table I are smaller than 4 for all cases except for the in air y irradiation which produces no observable gel in the present work. This result is consistent with Saito's theoretical finding that the gel formation occurs only when
174 Egusa, Ishigure, Tabata
Macromolecules
the G(S)/G(X) ratio is smaller than 4,8indicating that our method to evaluate the G(X) and G(S) values is not erroneous. In addition, the G values in Table I were obtained by using the same polystyrene sample and similar irradiation conditions between fast neutrons and y-rays. Therefore, it is reasonable to discuss the effects of LET and oxygen on G(X) and G(S), using the G values obtained in the present work. 2. LET Dependence of G(X) a n d G ( S ) . The 6oCo y-rays and fast neutrons incident upon polystyrene produce secondary electrons and recoil protons whose over-all LET is estimated to be ca. 0.02 and ca. 3.7 eV/A, respectively.2 The increase in LET enhances the value of 2G(X) + G(S) by a factor of 5.3-8.1 for in vacuo irradiation, as seen from Table I. If both cross-links and main-chain scissions result from macroradicals, this finding means that the number of macroradicals produced by the same amount of energy deposition is much larger for fast-neutron than for y-ray irradiation. The higher yield of macroradicals for fast neutrons can be explained qualitatively by the same mechanism as Burns and Jones used to account for the LET effect in aromatic substances such as benzene, biphenyl, and 0rthoterpheny1.l~They found that the G values of hydrogen formation and decomposition of these molecules increase with LET and interpreted the LET effect by the mechanism involving the competition between the deactivation of an excited molecule M* by the collision with a ground state molecule M (eq 5) and the
-
M*+M-+2M M* + M* radicals
(5) (6)
radical formation by the bimolecular reaction of the excited molecules (eq 6). This mechanism will apply for the y-ray and fast-neutron irradiations of polystyrene also. In this case, it is a monomer unit of the polymer that acts as M or M*, and the resulting radicals will be mainly hydrogen atoms and the side-group macroradicals. The excited monomer units of polystyrene will be produced more closely to one another for fast-neutron than for y-ray irradiation, since the microscopic energy deposition of high LET radiation is more inhomogeneous compared with that of low LET ones.20J1 Therefore, the higher yield of macroradicals for fast neutrons should be attributed to the bimolecular reaction of the excited monomer units (eq 6) a t the expense of the competing unimolecular reaction (eq 5). The results of in vacuo irradiations listed in Table I demonstrate that the increase in LET enhances the G(X) and G(S) values at the same time by factors of 4.3-7.3 and 7.5-11, respectively. If cross-link formation and mainchain scission of polystyrene proceed by the combination and dissociation" of the side-group macroradicals, respectively, and furthermore if these two types of reaction are simply competitive, then the G(S)/G(X) ratio is expected to be decreased by high LET radiations which favor the bimolecular reaction of macroradicals resulting in increased G(X) and decreased G(S) values. However, this expectation is incompatible with our result that the G(S)/G(X) ratio for in vacuo irradiation with fast neutrons is slightly higher than that with y-rays, as shown in Table I. This unexpected result can be explained by considering two types of cross-linking, viz., intermolecular cross-linking between two macromolecules and intramolecular crosslinking between two monomer units of the same macromolecule. Only the former is responsible for the observable change in the M, and M, values, and consequently our G(X) values are merely for this type of cross-linking. If therefore the intramolecular cross-linking is favored at high
LET, the G value of the competing intermolecular crosslinking, G(X), may be decreased so as to result in a higher ratio of G(S)/G(X) for fast-neutron than for y-ray irradiation. This idea may be reasonably accepted by taking into consideration the fact that the probability of simultaneous ionization and/or excitation of several segments in the same polymer chain is increased by high LET radiatiomn Furthermore, the evidence supporting the idea was actually obtained in the present work. The results of in vacuo irradiations in Table I show that the G(X) value for fast neutrons decreases from 0.264 to 0.142 with an increase in the initial molecular weight of polystyrene from 1.1 X lo5 to 3.9 X 105,while the G(X) value for y-rays decreases only slightly from 0.036 to 0.033. The G(X) dependence on the initial molecular weight has already been reported by Charlesby15for monodisperse polystyrene samples irradiated with 6oCoy-rays in vacuo. He derived the following semiempirical relationship between G(X) and the initial number-averagemolecular weight M," by taking into consideration the increasing contribution of intramolecular cross-linking with the increasing molecular size of polymers. G(X) = 0.047/(1 + 6.4 X 10-4(M,0)1/2) (7)23 The G(X) values calculated from this equation for M,O = 1.1X lo5 and 3.9 X lo5 are 0.039 and 0.034, respectively, which are in fair agreement with those obtained by y irradiation in the present work. If the contribution ratio of intermolecular to intramolecular cross-linking is independent of LET, the rate of decrease in G(X) when M,O is increased from 1.1 X lo5to 3.9 X lo5 will be the same between the y-ray and fast-neutron irradiations. However, the rate of decrease observed here is considerably higher for fast neutrons (46%) than for y-rays (6%). This finding can be taken as the evidence indicating that the intramolecular cross-linking is favored at high LET since the decrease in G(X) is just equal to the increase in the G value of intramolecular cross-linking. Accordingly, the higher ratio of G(S)/G(X) for fast neutrons than for y-rays is most likely ascribed mainly to the intramolecular cross-linking which is enhanced by high LET radiations at the expense of the competing intermolecular cross-linking. Several authors24have suggested that high LET radiations will produce localized regions of high temperatures (thermal spikes) along the tracks, and the temperature in the spikes will get temporarily much higher than the over-all temperature of a material under irradiation. If this suggestion holds true of polystyrene irradiated with fast neutrons, the higher ratio of G(S)/G(X) for fast neutrons than for y-rays may be ascribed in part to the thermal spikes, since it is reported that the G(S)/G(X) ratio of polystyrene irradiated withoC@ ' y-rays in vacuo increases with an increase in irradiation temperature of 30 to 100 OC.l' However, the temperature in the thermal spikes may be much higher than those mentioned above. Further studies are therefore required for a detailed discussion of the thermal spike contribution to the G(S)/G(X) ratio. 3. Influence of Oxygen on G(X) and G ( S ) . Comparison of the G(X) and G(S) values obtained in vacuo with those in air (Table I) demonstrates that the presence of oxygen increases the G(S) value by a factor of 5-8 for y-rays, whereas for fast neutrons it decreases both the G(X) and G(S) values to about 1/3 and 1/2 those obtained in vacuo, respectively. The increase in the G(S) value for in air irradiation with y-rays is most likely ascribed to the spontaneous dissociation of the peroxidic macroradical intermediate (oxi-
Cross-Linking and Degradation of Polystyrene 175
Vol. 13, No.1, January-February 1980
dative d e g r a d a t i ~ n ) .If~ ~therefore the peroxidic macroradical is formed by the reaction of oxygen with a sidegroup macroradical, the presence of oxygen will prevent .the combination of the side-group macroradicals resulting in a decreased G(X) value. However, the G(X) value observed for y irradiation in air is practically the same as that in vacuo, as shown in Table I. This fact suggests another mechanism for the peroxidic macroradical formation, for instance M* O2 peroxidic macroradical (8) where M* stands for an excited monomer unit of polystyrene. If this reaction actually occurs at low LET, it would increase the G(S) value alone without significant influence on the G(X) value. For fast neutrons of high LET, on the other hand, another reaction mechanism of oxygen must be taken into account in order to explain the simultaneous decrease in G(X) and G(S) by the presence of oxygen, for instance M* M* 0 2 + 2 M 02* (9)
2.0 h
I
-
+
+
+
+
where oxygen acts as a quencher of excited monomer units M*. This reaction would compete with the macroradical formation (eq 6), decreasing the yield of macroradicals which either form cross-links or undergo main-chain scissions. This mechanism would explain not only the simultaneous decrease in G(X) and G(S) by the presence of oxygen but also relatively small differences in the G(S)/G(X) ratio between the in vacuo and in air irradiations with fast neutrons (Table I). However, no evidence supporting these postulated reactions of oxygen (eq 8 and 9) is available a t the present stage. Further studies are therefore required for a detailed discussion of the reaction mechanism of oxygen during irradiation of polystyrene. 4. LET Dependence of Change in Molecular Weight Distribution. It is clear that the characteristics of the M w / M , , and M J M , changes with ux shown in Figure 4 are related primarily to a difference in the G(S)/G(X) ratio which arises as a result of the LET effects due to fast neutrons and y-rays. For in air irradiations, in fact, the G(S)/G(X) ratio (Table I) differs by a factor of 2-5 between fast neutrons and y-rays. Therefore, the difference in the M w / M nand M z / M wchanges with ux between the two types of radiation (Figure 4b) should be ascribed mainly to the difference in the G(S)/G(X) ratio. For in ‘vacuo irradiations, on the other hand, the G(S)/G(X) ratio differs only by a factor of 1.5-1.7 between fast neutrons and y-rays. This result suggests that the more rapidly increasing ratio of M z / M wwith ux for fast neutrons than for y-rays (Figure 4a) should be ascribed to factors other than the G(S)/G(X) ratio. The molecular weight distributions after in vacuo irradiations with fast neutrons and y-rays are compared in Figure 5 when the number of cross-linked units per initial number-average molecule is the same for both types of radiation (ux = 0.26). These distributions are normalized so as tc become unity when integrated by molecular weight M from zero to infinity, and hence it can be seen that the distribution for fast neutrons (solid curve) has a higher weight fraction than that for y-rays (dash-dot curve) in the molecular weight region of initial polystyrene (broken curve) and above ca. 6 X lo6. These characteristics in the molecular weight distribution change (Figure 5) and in the M z / M wchange with ux (Figure 4a) are considered to be ascribed to the same factor which causes the nonrandom degradation of PMMA,2 i.e., the inhomogeneous energy deposition of fast neutrons on a microscopic scale. In order to confirm this view, we carried out the computer simulation of the nonrandom cross-linking on the
0
I
5
6
log M
I
8
F i g u r e 5. Comparison of the molecular weight distributions changed by in vacuo irradiations with @Coy-rays (dash-dot curve) and fast neutrons (solid curve) to the same ux value of 0.26 for polystyrene with an initial molecular weight of 3.9 X 10s (broken curve). See the text for ux.
same basis as previously described for the nonrandom degradation of PMMA.2 When the total absorbed dose in a polymer system is increased by AD, let the increment be absorbed exclusively in a small part whose fraction to the whole system is x . In this case, the increment of absorbed dose within the small part becomes A D l x , which is taken as a parameter expressing the degree of the microscopic inhomogeneity of energy deposition. We assume further that this process of energy deposition has been repeated independently N times when the totaldose in the whole system is D, i.e., D = ADN. When x